Composition of nanocomposite containing graphene sheets

ABSTRACT

A novel nanocomposite having graphene sheets is described. The nanocomposite may be used for medical devices such as bone cement, dentures, paper, paint and automotive industries. A novel Microwave irradiation (MWI) was used to obtain R-(GO-(STY-co-MMA)). The results indicate that the nanocomposite obtained using the MWI had a better morphology and dispersion with enhanced thermal stability compared with the nanocomposite prepared without MWI. An average increase of 136% in hardness and 76% in elastic modulus were achieved through the addition of only 2.0 wt % of RGO nanocomposite obtained via the MWI method.

CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional application and claims priority to U.S. patent application Ser. No. 13/873,329 filed on 30 Apr. 2013, now allowed. The pending U.S. application Ser. No. 13/873,329 is hereby incorporated by reference in its entireties for all of its teachings.

FIELD OF TECHNOLOGY

The present disclosure relates to a novel composition for a nanocomposite containing graphene sheets.

BACKGROUND

Graphene (GR) is known as the thinnest two-dimensional graphitic carbon (sp²-bonded carbon sheet) material and is one atom in thickness [Hassan et. al. 2009, Huang et al. 2011, Kuilla et al. 2010]. GR has recently attracted much interest as filler for the development of new nanocomposite. Its extraordinary structural, mechanical, thermal, optical and electrical properties make GR an excellent two-dimensional filler material for polymer composite for application in many technological fields.

However, one of many challenges is achieving good dispersion of the nanoscale filler GR, which has a strong tendency to agglomerate due to intrinsic van der Waals forces, in the composite. Good dispersion is crucial for achieving the desired enhancement in the final physical and chemical properties of the composite. There is a need to find an optimal method to create a nanocomposite that has superior physical and chemical properties and is easy to make.

SUMMARY

The present disclosure describes a composition and its use for various industrial uses. In one embodiment, a composition for a nanocomposite having graphene sheet is described.

The nanocomposite, in one embodiment, is made by using microwave irradiation (MWI). In another embodiment, the nanocomposite comprises of graphene, styrene and methyl methacrylate. In one embodiment, the nanocomposite is used for medical devices/articles such as bone cement, dentures, paper, paint and automotive article. In another embodiment, the nanocomposite has a superior nanomechanical properties compared to non MWI method of preparation.

In one embodiment, a method of making nanocomposite is by synthesizing reduced graphene oxide powder. In another embodiment, styrene and methyl methacrylate is mixed in a specific weight ratio. The ratio is 1:1. In another embodiment, specific time and specific temperatures are used for performing various steps to obtain a copolymer of ST-co-MMA polymer with graphene sheets that is called a nanocomposite in the instant invention.

The composition of the nanocomposite and using the nanocomposite disclosed herein may be implemented in any means for achieving various aspects, and may be executed to be used for various industrial applications including medical and non-medical applications. Other features will be apparent from the accompanying drawings and from the detailed description that follows.

BRIEF DESCRIPTION OF FIGURES

FIG. 1. Digital camera photograph of (a) neat poly(STY-co-MMA), (b) and (c) RGO-(STY-co-MMA) nanocomposite, (d) R-(GO-(STY-co-MMA)) nanocomposite. Powders obtained after solvent evaporation and drying the samples at room temperature

FIG. 2. FTIR spectra of (a) GO, (b) GR, (c) neat poly(STY-co-MMA), (d) RGO-(STY-co-MMA) nanocomposite, (e) R-(GO-(STY-co-MMA)) nanocomposite

FIG. 3. ¹H NMR spectra of (a) neat poly(STY-co-MMA), (b) RGO-(STY-co-MMA) nanocomposite, (c) R-(GO-(STY-co-MMA)) nanocomposite/using CDCl₃ solvent

FIG. 4. ¹³C NMR spectra of (a) neat poly(STY-co-MMA), (b) RGO-(STY-co-MMA) nanocomposite, (c) R-(GO-(STY-co-MMA)) nanocomposite/using CDCl₃ solvent

FIG. 5. The Raman spectra of (a) GO, (b) GR (c) neat poly(STY-co-MMA), (d) RGO-(STY-co-MMA) nanocomposite

FIG. 6. XRD patterns of (a) graphite, (b) GO, (c) GR, (d) neat poly(STY-co-MMA), (e) RGO-(STY-co-MMA) nanocomposite, (f) R-(GO-(STY-co-MMA)) nanocomposite

FIG. 7. The SEM micrographs of (a) Graphite, (b) GO, (c) GR, (d) neat poly(STY-co-MMA), (e) RGO-(STY-co-MMA) nanocomposite, (f) R-(GO-(STY-co-MMA)) nanocomposite

FIG. 8. The HR-TEM images of (a) graphene (GR), (b) neat poly(STY-co-MMA), (c) RGO-(STY-co-MMA) nanocomposite, and (d) R-(GO-(STY-co-MMA)) nanocomposite

FIG. 9. TGA thermograms of neat copolymer, in situ RGO-copolymer nanocomposite, and MWI RGO-copolymer nanocomposite.

FIG. 10. DSC curves of (a) neat poly(STY-co-MMA), (b) RGO-(STY-co-MMA) nanocomposite, (c) R-(GO-(STY-co-MMA)) nanocomposite.

Other features of the present embodiments will be apparent from the accompanying drawings and from the detailed description that follows.

DETAILED DESCRIPTION

In the instant invention the composition and preparation of the nanocomposite (using in situ and microwave method), characterization and evaluation of the chemical, structural properties, thermal behavior and intercalation and/or exfoliation, dispersion of graphene (GR) sheet is described.

The description describes the materials used for making the nanocomposite as well as other means of making the composite to be compared with the instant invention.

One of the advantages of graphene or graphene oxide (GO) is that it can be well-dispersed in water and physiological environments because of its abundant hydrophilic groups, such as hydroxyl, epoxide and carboxylic groups, on its surfaces. Graphene has recently attracted interest from researchers as a filler material in new composite polymers. The structural, mechanical, thermal, optical and electrical properties of graphene make it an excellent two-dimensional filler material for polymer composite that may find applications in numerous technological fields.

Various techniques have been developed for the synthesis of such composite structures, including solution mixing, melt blending, in situ polymerization and in situ polymerization using microwave irradiation (MWI). The MWI method offers a fast and easy way to synthesize graphene-based materials. In MWI, dielectric heating energy is transferred directly to the reactants. Energy is supplied to the molecules faster than they are able to relax, which creates high instantaneous temperatures and increases the yield and quality of the products. The co-polymer of methyl methacrylate and styrene (MMA-co-STY) is an important polymeric material that has numerous applications in medicine (e.g., as bone cement), dentistry (e.g., dentures) and the paper, paint and automotive industries.

In the instant invention we present our characterization of nanocomposite material that contains co-polymers (STY-co-MMA) with graphene sheets.

Experimental Section—Materials:

Extra pure graphite powder (>99.5%) was purchased from Merck (Germany), and hydrazine hydrate (HH, 80%) was obtained from Loba Chemi. Pvt. Ltd (India). Styrene (STY) and Methyl methacrylate (MMA) monomers (Acros Chemical Co., UK, 99%) were kept in a refrigerator and used as received. Benzoyl peroxide (BP) (BDH Chemicals Ltd., UK) was used as an initiator. Potassium permanganate (KMNO₄, >99%) and hydrogen peroxide (H₂O₂, 30%) were obtained from Merck (Germany). Other solvents and chemicals were of analytical grade and used without further purification.

Preparation of GR Oxide (GO):

GO was synthesized from the oxidation of graphite powder via the Hummers and Offeman method. Natural graphite (3.5 g) was added to 100 ml of 98% H₂SO₄ under vigorous stirring. KMNO₄ (10 g) was slowly added, and the temperature was maintained below 20° C. The stirring was continued for 1-2 hrs at 35° C. Then, the content of the flask was poured into 500 ml of deionized water, and a sufficient amount of H₂O₂ (20 ml of a 30% aqueous solution) was added to destroy any excess permanganate. Upon treatment with the peroxide, the suspension turned bright yellow. GO was isolated by filtration through a sintered glass filter. The product was thoroughly washed with dilute HCl and then hot water to remove the residual sulfate ions yielding a yellow-brown filter cake. After repeated washing of the resulting yellowish-brown cake with hot water, the GO was dried at 80° C.

Preparation of Reduced GO (RGO):

The dried GO (400 mg) was stirred and sonicated in 20 ml of deionized water until a homogeneous yellow dispersion was obtained. The GO can be dispersed easily in water due to the presence of a variety of hydrophilic oxygen groups (OH, O and COOH) on the basal planes and edges. The solution was placed inside a conventional microwave after the addition of 400 μl of the HH reducing agent. The microwave oven (KenWood MW740) was operated at full power (900 W) in 30 s cycles (on for 10 s and off and stirring for 20 s) for a total reaction time of 2 min. The yellow dispersion of GO gradually changed to a black color indicating the completion of the chemical reduction to GR. The GR sheets were separated using a centrifuge (Centurion Scientific Ltd.) operated at 5000 rpm for 15 min and dried at 80° C. overnight.

In Situ Preparation of RGO-(STY-Co-MMA) Composite:

RGO powder (2.0 (wt./wt. %)) was added to the STY and MMA (1:1 wt %) mixture, stirred and sonicated for 1 hr. Soon after the BP initiator (5.0 wt %) was added to the suspension and stirred until the initiator was dissolved. And then the mixture was heated and maintained at 60° C. for 20 h to promote polymerization using shaking-water bath (GFL). After the polymerization was complete, the product was poured into an excess of methanol, stirred for 15 minutes, and washed with hot water; it was the filtered and dried in an oven at 80° C. overnight.

Preparation of R-(GO-(STY-Co-MMA)) Nanocomposite by MWI:

GO powder (2.0 (wt./wt. %)) was added to the STY and MMA (1:1 wt %) mixture, stirred and sonicated for 1 hr. Then BP initiator (5.0 wt. %) was added to the suspension and stirred until the initiator dissolved. Then, the reaction mixture was maintained at 60° C. for 20 h to promote polymerization using a shaking-water bath (GFL). After the polymerization finished, the product was poured into an excess of methanol, stirred for 15 min and washed with hot water. Then, the product was filtered and dried at 80° C. overnight. Four hundred milligrams of the dried composite of GO-polymers were dissolved in solvent, stirred and sonicated for 1 h. Then, the composite was placed inside a conventional microwave oven (Kenwood MW740) following the addition of 400 μl of HH. The microwave oven was operated at full power (900 W) in 30 s cycles (on for 10 s and off and stirring for 20 s) for a total reaction time of 2 min. Then, the composite were separated using a centrifuge (Centurion Scientific Ltd.) operated at 5000 rpm for 15 min and dried in an oven at 80° C. overnight. For comparison, the neat poly(STY-co-MMA) was prepared via a similar procedure in the absence of the RGO and GO.

Instrumentation and Characterization:

The FTIR (Thermo Scientific Nicolet-iS10) spectra of the nanocomposite were recorded in the range of 4000-500 cm⁻¹. The ¹H NMR of the solution was recorded on a Bruker Avance (III) at 400 MHz using CDCl₃ as the solvent, and the nanocomposite were macerated in a solvent for 1 day. The Raman spectra of nanocomposite were measured with a Bruker Equinox 55 FT-IR spectrometer equipped with an FRA106/S FT-Raman module and a liquid N₂-cooled Ge detector using the 1064 nm line of a Nd:YAG laser with an output laser power of 200 mW. The X-ray diffraction (Philips-Holland, PW 1729) of the nanocomposite were investigated with Cu radiation (30 kV, 40 mA, Kα radiation (λ=1.54430 Å)) between 2θ of 5° and 100°. The thermogravimetric analyses (TGA) of the nanocomposite were studied using a NETZCH 209 F1 thermogravimetric analyzer. The decomposition temperature measurements using TGA were performed under an N₂ atmosphere at a heating rate of 10° C. per minute from 25° C. to 800° C. Differential scanning calorimetry (DSC, NETZCH 204 F1) measurements were employed to estimate the glass-transition temperature (T_(g)) of each nanocomposite. The nanocomposite were heated from −25° C. to 100° C. at a heating rate of 10° C. per min. Then, a double run was performed after cooling at a heating rate of 2° C. per min from 25° C. to 350° C. The T_(g) was taken as the midpoint of the transition. A scanning electron microscope (SEM, FEI Quanta 200) was employed to study the morphology of the nanocomposite after they were mounted on the nanocomposite slabs and coated with gold via sputtering system (Polaron E6100, Bio-Rad). Ultrathin sections of the composite were prepared for high resolution transmission electron microscopy (HR-TEM) studies; the high resolution transmission electron microscope (JEOL JSM-2100F, JEOL) was operated at 200 kV. A drop of the composite dispersed in ethanol was placed on copper grids and dried for studies.

Results and Discussion

Copolymers and Graphene-Copolymers Composite by In Situ and MWI:

Following the procedure of in situ and MWI reduction methods, the solvent can be dried and the RGO-(STY-co-MMA) composite can be recovered in the film form, and a powder form for R-(GO-(STY-co-MMA)) composite. These composite are different from pristine graphene and neat copolymer. FIG. 1 shows the dried samples of poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite obtained from in situ and MWI methods.

FTIR spectral analysis was performed to confirm the chemical structure of all copolymers. FIG. 2 shows the FTIR spectra of Graphene Oxide (GO), Graphene (GR), poly(STY-co-MMA), RGO-(STY-co-MMA) nanocomposite, and R-(GO-(STY-co-MMA)) nanocomposite. The characteristic FTIR features of GO (FIG. 2 line a) include the presence of different types of oxygen functionalities, which have been confirmed by the band at 3400 cm⁻¹, which corresponds with the O—H group, the bands at 1720 and 1610 cm⁻¹, which corresponds with the C═O carbonyl/carboxyl and C═C aromatic groups, respectively, and the band at 1220 cm⁻¹, which corresponds with the C═O in the epoxide group. For the reduced GR oxide (FIG. 2 line b) indicates that the O—H band at 3430 cm⁻¹ was reduced in intensity due to the deoxygenation of the GO-oxygenated functionalities. The spectrum of GR also contains bands at 1627 cm⁻¹ and 1139 cm⁻¹, which correspond to C═C and C—O groups, respectively. The FTIR spectrum of the prepared poly(STY-co-MMA) as shown in (FIG. 2 line c) exhibits several characteristic four peaks at 3000-3100 cm⁻¹ due to Ar—H and ═C—H stretching, 2947 and 2853 cm⁻¹ due to C—H stretching vibrations of methyl, methylene and methine groups, 1730 cm⁻¹ due to C═O stretching vibrations of ester carbonyl, 1602 cm⁻¹ due to aromatic C═C stretching vibrations, 1450-1390 cm⁻¹ due to C═H deformation bands, 1160-1120 cm⁻¹ due to C═O═C stretching vibrations. This is with agreement with the previously reported results for the neat copolymer [12]. (FIGS. 2 line d and 2 line e) also displays the FTIR spectra of RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite. The resemblance of characteristic bands compared to the prepared neat poly(STY-co-MMA) indicates that there is no structural effect when MWI method was used to interrelate graphene into the poly(STY-co-MMA). The FTIR spectrum of RGO-(STY-co-MMA) composite (FIG. 2 line d) shows peaks at 3431 cm⁻¹ due to O—H stretching vibrations, 2925 and 2848 cm⁻¹ due to C—H stretching vibrations of methyl, methylene and methine groups, 1733 cm⁻¹ due to C═O stretching vibrations of ester carbonyl, 1627 cm⁻¹ due to aromatic C═C stretching vibrations, 1450-1383 cm⁻¹ due to C—H deformation bands, 1170-1114 cm⁻¹ due to C—O—C stretching vibrations. When MWI was employed in the preparation R-(GO-(STY-co-MMA)) composite (FIG. 2 line e), there was an increase in the intensity of the C═O bands and a decrease in the intensity of the C═C bands (at 1700 and 1653 cm⁻¹, respectively). In addition, the characteristic bands associated with aliphatic C—H and —CH₂ groups were observed at 2936 and 2831 cm⁻¹, respectively. Peaks at 3000-3100 cm⁻¹ due to Ar—H and ═C—H stretching. In the spectrum of the R-(GO-(STY-co-MMA)) composite compared with that obtained from the in situ method (FIG. 2 d), there were some changes in intensity, shifts and emerging of some peaks in the regions of (C═O, C═C, Ar—H, ═C—H, and C—O—C), these evidences indicate intercalation between these groups and R-(GO-(STY-co-MMA)) composite using MWI method stronger than that of RGO-(STY-co-MMA) composite using in situ method. In summary, the results from FTIR spectroscopy suggest that all of the nanocomposite exhibit the characteristic peaks for poly(STY-co-MMA) chains and GR sheets.

Another structural-evidence can be obtained from ¹H-NMR and ¹³C-NMR. FIGS. 3A, 3B and 3C display ¹H-NMR spectra of neat poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite. The peaks at δ=˜0.6-1.0 ppm represented —CH₃ (for MMA unit) and those between δ=˜1.3 and 2 ppm corresponded to —CH₂ (for both MMA and STY units) and —CH (for STY unit). It was reported that STY shows a peak at δ=7.1 ppm and MMA at δ=2.8-3.6 ppm corresponding to the phenyl ring (—C₆H₅) and the methoxy ester linkage (—COOCH₃), respectively. These peaks were identified in all copolymers. The relative peak areas due to phenyl and methoxy protons have been used to calculate copolymer composition. The composition of all composite is very close to the amounts of STY/MMA (0.96 mol %) in monomers feed.

The ¹³C-NMR spectra of neat poly(STY-co-MMA), RGO-(STY-co-MMA) composite, and R-(GO-(STY-co-MMA)) composite are shown in (FIG. 4A). The corresponding chemical shifts band at around 128 ppm has been observed in the sample of poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite and it has been assigned to carbon-carbon bonds in condensed aromatic structures. The ¹³C spectra of RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite also show essentially complete elimination of all epoxides (60 ppm region), almost as large a decrease in the alcohol content (70 ppm region) and the apparent elimination of any esters (again, much less intensity near 167 ppm). Peak around 176 ppm related to the carbon from aromatic carboxylic acids; (FIG. 4B) also indicated C═C bonds in the 126 ppm region, as well as the existence of carbonyl groups in the final product. The resonance at ˜134 ppm belongs to the un-oxidized sp² carbons of the graphene network. This signal for graphitic sp² carbon dominates both the RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite spectra (FIGS. 4A, 4C). This corresponds well with ¹H-NMR findings.

The composition of copolymer and copolymers composite were further studied by Raman spectroscopy (FIG. 5). The major scattering peaks of MMA and STY were observed. The observed peaks at 1448 cm⁻¹ and 1600 cm⁻¹ have been assigned to the CH₃ and C═C aromatic groups of MMA and STY, respectively. Comparison of the intensity of D band at 1300 cm⁻¹ and G band at 1600 cm⁻¹ (a well-accepted method for estimating the quality and structural order of graphitic structures [15]. RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite show that there is no significant difference in terms of influence defects in the structure of composite. The D band is related to the sp³ states of carbon, and it is used as a proof a disruption of the aromatic π-electrons system of graphene. The ratio of the intensities of the two bands (D/G), which should increase as a result of the interaction between π network in GR and C—OCH₃ and C═O in MMA and C═C in STY. The (D/G) band ratio for the GR is 0.66, where the ratio of RGO-(STY-co-MMA) composite is 0.77 (Table 2). This result indicates that the sp²-hybridized carbons were converted to sp³ hybridized carbons, which may be due to the covalent attachment of the GR sheets to the polymer. The ratio was the highest for the R-(GO-(STY-co-MMA)) composite, indicating a stronger covalent interaction than in the RGO-(STY-co-MMA) composite, which was prepared via in situ bulk polymerization.

TABLE 1 Summary of the D/G ratio determined from the Raman spectroscopy D band G band Sample 1300 1600 D/G ratio GO 0.052 0.036 1.44 GR 0.016 0.025 0.64 Poly(STY-co-PMMA) — — — RGO-(STY-co-MMA) 0.521 0.678 0.77 R-(GO-(STY-co-MMA)) — — —

The presence, intercalation and/or exfoliation and dispersion of GR sheets in the polymer matrix can be evaluated using XRD. The XRD pattern of the graphite displayed in (FIG. 6 a) showed a strong characteristic peak at 2θ=26.54°, with a d-spacing of 0.34 nm. The XRD pattern of GO displayed in (FIG. 6 b) showed a characteristic peak (2θ) at approximately 9.34°, which corresponds with a d-spacing of 0.95 nm. After GO was reduced by HH (FIG. 6 c), the d-spacing decreased. In addition, the peak appeared at 2θ=12.42°, with a d-spacing of 0.71 nm. This result confirms the chemical reduction of GO and formation of GR via the HH reducing agent. In addition, this result also indicates the removal of large number of oxygen-containing groups and the formation of much more exfoliated GR sheets, as well as a change in the hybridization of the reduced carbon atoms from tetrahedral sp³ to planar sp². The characteristic diffraction peak of the poly(STY-co-MMA) (FIG. 6 d) indicated an amorphous structure with 2θ=27.20° with a d-spacing of 0.328 nm. After loading GR to the co-polymer matrix, the RGO-(STY-co-MMA) composite resulted in 2θ=27.85° with a d-spacing of 0.321 nm. Finally, R-(GO-(STY-co-MMA)) composite showed a decrease in the d-spacing which appeared at 2θ=28.56° with a d-spacing of 0.313 nm. Only one broad diffraction peak relating to the diffraction peak of the poly(STY-co-MMA) in the composite (FIGS. 6 d, 6 e and 6 f) was observed indicating an amorphous structure. Using MWI method, the XRD pattern of R-(GO-(STY-co-MMA)) composite had less d-spacing than RGO-(STY-co-MMA) composite, suggesting more stacking in the layers and indicating reduced attractive interactions among graphene-(STY/MMA) co-polymer matrix, making their exfoliation into individual sheets possible. A similar trend of changes in d-spacing can be observed for the peaks at 2θ=36.7° where the 2θ value decreased for RGO-(STY-co-MMA) composite and increased for R-(GO-(STY-co-MMA)). The relative level of crystalinity was higher for the R-(GO-(STY-co-MMA)) composite as the peak width (e.g. at 2θ=28.56° decreased in comparison for the same peak for RGO-(STY-co-MMA) at 2θ=27.85°, indicating agglomeration in these (i.e., RGO-(STY-co-MMA) composite. This agglomeration may arise from strong van der Waals interactions between the reduced GR sheets. Similarly, both composite polymers indicate sharper peak in comparison to the poly(STY-co-MMA) e.g. at 2θ=27.20°. Moreover, the absence of the characteristic peaks of GO and GR in the composite indicate that the graphene platelets in GR have been exfoliated.

Direct evidence of exfoliation of the graphene in the final polymer composite can be obtained from SEM and HR-TEM; also it provides images of dispersion of graphene layers in neat (STY/MMA) copolymer matrix. FIG. 7 a shows the SEM image of the graphite. The particles have a plate-like shape with average sizes of 1-10 μm. The prepared GO (FIG. 7 b) were not fully exfoliated and had a flaky texture. This result suggests a partially exfoliated structure and reflects its layered microstructure containing large interlayer spacing and thick multilayer stacks, which is in agreement with the literature. FIG. 7 c shows the SEM image of GR, which reveals that the GR consisted of randomly aggregated, thin, crumpled sheets that are closely associated with each other, forming a disordered solid. The SEM of neat poly(STY-co-MMA) (FIG. 7 d) reveals existence common stacks of lamellae structure. RGO-(STY-co-MMA) image (FIG. 7 e) shows very uneven terrain as well as the edge displaying protrusions. R-(GO-(STY-co-MMA)) (FIG. 7 f) shows well established parallel-oriented lamellar structure. A comparison of the micrographs in FIG. 7 e and FIG. 7 f, the morphology is clearly different than that of the neat co-polymer (FIG. 7 d), with a visible ‘web-like’ network between the edges of the copolymer.

Because SEM cannot spatially resolve the thickness of an individual GR-based sheet, high resolution transmission electron microscopy (HR-TEM) was employed to determine if the GR-based sheets were indeed present in the composite as single exfoliated sheets or as multi-layered sheets. HR-TEM offers direct evidence for the formation of the GR nanosheets on the polymer composite. HR-TEM of GR, neat poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite are shown in (FIG. 8). The graphene (GR) (FIG. 8 a) shows clearly visible structure of the individual layers. FIG. 8 b shows the HR-TEM image of neat poly(STY-co-MMA), showing a uniform gray level with different stack lamellae, indicating a miscible copolymer matrix. RGO-(STY-co-MMA) composite (FIG. 8 c) show dark regions of GR platelets not randomly dispersed within the copolymer matrix. The dark heterogeneous regions, which show that there exist thick layers composed of several GR platelets. The R-(GO-(STY-co-MMA)) HR-TEM image (FIG. 8 d) shows dark regions and visible boundaries between the GR platelets and copolymer matrix, and the layers clearly maintain their common orientation. This shows that the GR sheets, whose transparency for electron beam is better compared to those of (FIG. 8 c), are finely dispersed in the matrix of the (STY/MMA) co-polymer and are oriented to a specific direction; in addition, the channels in this sample are more diffused. These results indicate that delamination of the GR platelets were effectively induced by the copolymerization and were effectively reduced by MWI to yield exfoliated RGO-(STY-co-MMA) composite. These results also indicate that MWI can improve the dispersion of GR in the matrix.

The thermo-gravimetric analysis (TGA) and differential scanning calorimetry (DSC) measurements were performed on co-polymer and co-polymer composite to examine the effect of the graphene content on the thermal stability. The TGA and DSC results of poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite are displayed in FIG. 9 and summarized in Table 3. There is no significant weight loss of the neat poly(STY-co-MMA) below 400° C. The thermal degradation of neat poly(STY-co-MMA) only occurs in one step at 405° C. The TGA of RGO-(STY-co-MMA) composite follow three stage weight loss regions. The first weight loss was observed in the range 130-230° C. (˜15%) which corresponds to the loss of graphene. The second weight loss from 230-390° C. (˜10%) which corresponds to the loss of graphene. The main chain of RGO-(STY-co-MMA) composite (˜70%) decomposes at 410° C. In the case of R-(GO-(STY-co-MMA)) composite, TGA thermogram shows more homogenous behavior with only (5%) weight loss on heating to 220° C. and the main chain decomposes at 393° C. (˜90%). This clearly shows that R-(GO-(STY-co-MMA)) composite are more thermal stable relative to the RGO-(STY-co-MMA) composite prepared by in situ method. Moreover, R-(GO-(STY-co-MMA)) and RGO-(STY-co-MMA) the composite generally resulted in a slight decrease in the thermal stability of the composite related to the neat poly(STY-co-MMA).

To further understand the thermal behavior and homogeneity of the composite prepared by the two different methods, differential scanning calorimetry (DSC) of the neat poly(STY-co-MMA), RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) composite was employed to compare the glass transition temperature (T_(g)) of the polymer itself with the composite. The DSC curves of all synthesized poly(STY-co-MMA) are shown in (FIG. 10) and the T_(g) data are also summarized in Table 3. The T_(g) values of neat poly(STY-co-MMA) was 93° C. The T_(g) of RGO-(STY-co-MMA) nanocomposite was 89.5° C., while R-(GO-(STY-co-MMA)) composite show T_(g) of 119° C. Interestingly the glass transition temperature (T_(g)) of R-(GO-(STY-co-MMA)) composite (T_(g)=119° C.) is higher than the T_(g) of the poly(STY-co-MMA), (T_(g)=93° C.). This indicates that our approach, to intercalate the graphene into poly(STY-co-MMA) using MWI method, clearly enhance the thermal properties of the copolymer. This T_(g) shift has been attributed to the presence of so called ‘interphase’ polymer networking, which arises due to the interaction of the chains with the graphene platelet surface, which may restricted the mobility, creating an enormous volume of matrix polymer with increased T_(g). Percolation of this network of interphase polymer could then manifest the large T_(g) shift of the copolymer composite.

TABLE 2 Summary of thermal behavior data obtained from TGA and DSC measurements T_(degradation) T_(g) Sample (° C.) (° C.) GO 160 — GR 210 — PSTY 412 88.5 PMMA 290, 380 117.0 Poly(STY-co-MMA) 405 93.0 RGO-(STY-co-MMA) 190, 255, 407 89.5 R-(GO-(STY-co-MMA)) 393 119.0

The instant experiment proves that RGO-(STY-co-MMA) and R-(GO-(STY-co-MMA)) using in situ bulk polymerization facilitated by MWI was successfully prepared. Thermal analysis showed an enhancement in the thermal properties of the R-(GO-(STY-co-MMA)) nanocomposite prepared using MWI, which indicates that the RGO sheets efficiently reinforced the (STY-co-MMA)) matrix. Therefore, our approach is promising for the development of a new class of graphene-polymer nanocomposite. This investigation considered the relative changes in physical and thermal properties of composite in which GR was used as a nano-filler. The composite obtained using MWI exhibited a better morphology and increased dispersion with enhanced thermal stability. Therefore, our approach is promising for the development of a new class of graphene-polymer composite. In this disclosure composite and nanocomposite are used interchangeably.

In addition, it will be appreciated that the various composition of the nanocomposite and method of making the nanocomposite disclosed herein may be embodied using means for achieving the various combinations of material and irradiation doses using microwave. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. 

What is claimed is:
 1. A nanocomposite composition, comprising: a styrene added using a specific weight ratio; a methyl methacrylate equal to the ratio of the specific ratio of the styrene; and a graphene powder added using a weight/weight % of the styrene and methyl methacrylate ratio.
 2. The composition of claim 1, wherein the specific weight ratio for the styrene is
 1. 3. The composition of claim 1, wherein the specific weight ratio of the methyl methacrylate is
 1. 4. The composition of claim 1, wherein the weight/weight % for the graphene powder is
 2. 5. A nanocomposite composition, comprising: a graphene powder added using a weight/weight % of a styrene and methyl methacrylate ratio to be used for a specific article.
 6. The nanocomposite of claim 5, further comprising: the styrene added using a specific weight ratio, wherein the specific weight ratio for the styrene is 1; and the methyl methacrylate equal to the ratio of the specific ratio of the styrene.
 7. The composition of claim 6, wherein the specific weight ratio of the methyl methacrylate is
 1. 8. The composition of claim 5, wherein the weight/weight % for the graphene powder is
 2. 9. The composition of claim 5, wherein the specific article is at least one of a bone cement, denture, paper, paint and automotive industry article. 